mixtures of c12 -c18 n-paraffins with paraffinsulfonic acids having the same number of carbon atoms, water and sulfuric acid, and obtained by sulfoxidation of said paraffins with sulfur dioxide and oxygen in the presence of water and ultraviolet radiation are stripped of their excess sulfur dioxide and decanted to separate most of the paraffins, and obtain a residual mixture.

The residual mixture is fed with sulfuric acid until a two-phase system forms or at least until the mixture becomes turbid, and the turbid mixture or that floating on the heavy water-sulfuric acid phase is extracted with supercritical carbon dioxide, which removes with it the paraffins, which can be reused in the sulfoxidation process.

Patent
   4843184
Priority
Jul 23 1986
Filed
Jul 10 1987
Issued
Jun 27 1989
Expiry
Jul 10 2007

TERM.DISCL.
Assg.orig
Entity
Large
1
5
EXPIRED
1. A process for extracting c12 -c18 n-paraffins from a reaction mixture of c12 -c18 n-paraffins with paraffinsulfonic acids having the same number of carbon atoms, water and sulfuric acid, where said reaction mixture is obtained by sulfoxidation of a mixture of c12 -c18 paraffins at a temperature of between 25°-50°C with sulfur dioxide and oxygen in the presence of water and ultraviolet radiation, comprising the steps of;
(a) removing excess sulfur dioxide, if present, from said reaction mixture,
(b) decanting said reaction mixture to remove most of the c12 -c18 paraffins and to obtain a residual mixture,
(c) adding sulfuric acid to said residual mixture until a two-phase system forms, or at least until said residual mixture becomes a turbid mixture,
(d) separating a supernatant phase from said two-phase system, and
(e) extracting said turbid mixture or said supernatant phase with supercritical carbon dioxide.
2. A process as claimed in claim 1, wherein the quantity of sulfuric acid added is that minimum quantity which causes said residual mixture to become turbid.
3. A process as claimed in claim 1, wherein the sulfuric acid is oleum, concentrated sulfuric acid, or sulfuric acid diluted with water to a minimum concentration of 20% by weight.
4. A process as claimed in claim 1 and 3, wherein with 96% sulfuric acid the weight ratio of sulfuric acid to said residual mixture is at least 1:1.
5. A process as claimed in claim 1, wherein said extraction with supercritical carbon dioxide is carried out at a pressure of between 75 and 350 bar, a temperature of between 32°C-80°C and a weight ratio of carbon dioxide to paraffinsulfonic acids of between 1:1 and 50:1.
6. A process as claimed in claim 1, wherein about 96 wt % of sulfuric acid is added to said residual mixture until a two-phase system forms.
7. A process as claimed in claim 6, wherein said supernatant phase of said two-phase system, is extracted with supercritical carbon dioxide and the refined product contains between about 0.1-0.6 wt % c12 -c18 n-paraffins.
8. A process as claimed in claim 1, wherein about 96 wt % of sulfuric acid is added to said residual mixture until said residual mixture becomes a turbid mixture.
9. A process as claimed in claim 8, wherein said turbid mixture is extracted with supercritical carbon dioxide and the refined product contains between about 0.3-1.5 wt % c12 -c18 n-paraffins.
10. A process as claimed in claim 1, wherein about 70 wt % of sulfuric acid is added to said residual mixture until a two-phase system forms.
11. A process as claimed in claim 10, wherein said supernatant phase of said two-phase system, is extracted with supercritical carbon dioxide and the refined product contains about 0.02 wt % c12 -c18 n-paraffins.

This invention relates to a process for extracting n-paraffins from their mixtures with paraffinsulfonic acids.

Paraffinsulfonic acids containing between 12 and 18 carbon atoms are generally prepared by sulfoxidation of C12 -C18 paraffins with sulfur dioxide (SO2) and oxygen (O2) in the presence of water (H2 O), using ultraviolet (UV) radiation for reaction initiation.

The reaction product obtained from the sulfoxidation reaction consists of a mixture containing small percentages of paraffinsulfonic acids, H2 O and sulfuric acid (H2 SO4), but mostly unreacted n-paraffins.

Most of the n-paraffins can be easily separated from said mixture, but a substantial fraction of them will remain together with the H2 SO4, the H2 O and the paraffinsulfonic acids. It is important to note that the n-paraffins must be separated to the maximum possible extent not only for obvious economic reasons, but also because their presence in paraffinsulfonic acids is undesirable.

The known art gives suggestions for separating n-paraffins from the rest of the H2 SO4, paraffinsulfonic acid and H2 O mixture. One of these suggestions is contained in European patent application No. 131913, in particular in Example 1. In No. 131913, Example 1, the mixture containing paraffinsulfonic acids, unreacted n-paraffins, H2 O and H2 SO4 is treated with isopropanol in a quantity of 15%, to separate the mixture into three distinct phases; the upper one essentially consisting of n-paraffins, the lower one consisting of H2 O, H2 SO4 and isopropanol, and the intermediate one containing paraffinsulfonic acids, H2 SO4, H2 O, n-paraffins and isopropanol.

The intermediate phase is then mixed with methylene chloride to separate an aqueous H2 SO4 phase containing isopropanol and a little methylene chloride from a phase containing paraffinsulfonic acids, n-paraffins, H2 O, methylene chloride and H2 SO4. It is neutralized with soda and concentrated. Finally it is heated to a temperature of 200°C to distill off the n-paraffins.

This procedure for removing the n-paraffins is obviously complicated, and notwithstanding its various extraction stages it is still necessary to use high-temperature vaporization at the end, which in all cases damages the product obtained.

With the known process it is therefore not possible to prepare free paraffinsulfonic acids or their salts with weak bases, as these are unstable at high temperature.

It has been surprisingly found that the previously described drawbacks of the known art regarding the separation of n-paraffins can be obviated in a simple manner by adding H2 SO4 to the mixture of paraffinsulfonic acids, H2 SO4, H2 O and paraffins until a two-phase system forms or at least until the mixture becomes turbid. Then the turbid mixture or the supernatant phase of the two-phase system is extracted with carbon dioxide (CO2) under supercritical conditions.

The present invention provides a process for removing n-paraffins containing between 12 and 18 carbon atoms from mixtures of said n-paraffins with paraffinsulfonic acids having the same number of carbon atoms, H2 O and H2 SO4. The mixtures are obtained by sulfoxidation of C12 -C18 n-paraffin mixtures at a temperature of between 25° and 50°C with SO2 and O2 in the presence of H2 O and UV radiation. Excess SO2, is removed if present, from the reaction mixture originating from the paraffinsulfonic acid synthesis reaction. The mixture is decanted to remove most of the C12 -C18 n-paraffins. The characteristic of the process is that the residual mixture obtained after removing the SO2 and the decanted paraffins is fed with H2 SO4 until a two-phase system forms, or at least until the residual mixture becomes turbid. The turbid mixture or the supernatant phase of the two-phase system is then extracted with supercritical CO2.

With regard to the quality of H2 SO4 used according to the invention to form the two-phase system, this can be oleum, concentrated H2 SO4 or H2 SO4 diluted with H2 O to a minimum H2 SO4 concentration of 20% by weight. With regard to the formation of the two-phase system due to the addition of H2 SO4, it commences with the mixture becoming turbid and proceeds as further H2 SO4 is added, to give sharp separation of a heavy phase consisting of H2 O and H2 SO4 from a supernatant phase.

The mixture to be subjected to extraction with supercritical CO2 is either the turbid mixture formed by adding the minimum quantity of H2 SO4 or the supernatant mixture after separation from the heavy mixture of H2 SO4 and H2 O obtained by adding H2 SO4 in a quantity exceeding the minimum, this latter as stated being that required to cause mixture turbidity. With 96% H2 SO4, the weight ratio of H2 SO4 to residual mixture can attain a value of 1:1 or higher.

With regard to the conditions under which the turbid or aforesaid supernatant mixture is extracted with supercritical CO2, these are as follows:

______________________________________
Extraction temperature:
between 32 and 80°C
Extraction pressure:
between 75 and 350 bar
Weight ratio of CO2 used for extraction to
______________________________________

The paraffinsulfonic acid mixture resulting from the process according to the present invention is then generally neutralized in known manner using chosen bases to thus obtain paraffin sulfonates of any desired type.

The H2 SO4 contained in the mixture resulting from the process of the present invention, in the case of extraction of the supernatant phase with supercritical CO2, is less in quantity than that present before the treatment and can be separated, if required, by methods known in the art, such as mixing with suitable substances or precipitation to form insoluble salts. Some examples are given hereinafter to better illustrate the invention, but without intending to limit it thereto or thereby.

A laboratory extraction apparatus was used consisting essentially of an extraction vessel into which the mixture containing the product to be extracted with supercritical CO2 was fed, and a separator from which the CO2, separated from the extracted substance, was recycled to the extractor by a metering pump after condensation.

401.0 g of crude mixture (with decantable n-paraffins and SO2 removed) of paraffinsulfonic acids obtained by sulfoxidation of C12 -C18 n-paraffins, and having the following composition:

______________________________________
paraffinsulfonic acids
24.74% by weight
C12 -C18 n-paraffins
26.46% by weight
H2 O 40.94% by weight
H2 SO4 7.86% by weight
______________________________________

were treated with 80.0 g of 96 wt % H2 SO4 at ambient temperature in a separator funnel.

After decantation, two phases were separated. The lower phase (213.5 g) consisted of H2 O and H2 SO4 ; the upper phase (267.5 g) contained all the n-paraffins and paraffinsulfonic acids present in the feed, together with H2 O and H2 SO4.

105.8 g of the upper phase product were extracted with supercritical CO2.

The extraction was effected at 45°C at 150 bar; the CO2 throughput was maintained constant at 1.72 kg/h. After one hour, the CO2 feed was interrupted and the refined product contained in the extractor was discharged.

Analysis of this product gave the following results:

______________________________________
paraffinsulfonic acids
62.29% by weight
C12 -C18 n-paraffins
0.11% by weight
H2 O 26.47% by weight
H2 SO4 11.13% by weight
______________________________________

The extracted n-paraffins are practically pure and can be recycled to the sulfoxidation reaction without any treatment.

3149.7 g of a crude mixture (as heretofore defined) of paraffinsulfonic acids having the composition indicated in Example 1 were treated with 158.1 g of 96 wt % H2 SO4. After separating the lower phase (92.6 g) consisting of H2 O and H2 SO4, the upper phase was again treated with 96 wt % H2 SO4 (161.1 g). A lower phase was separated (827.2 g) consisting of H2 O and H2 SO4, and the upper phase was again treated with 160.3 g of 96 wt % H2 SO4. A lower phase was separated (392.4 g) consisting of H2 O and H2 SO4 sulphuric acid. The resultant upper phase (1918.1 g) was extracted with supercritical CO2. Fifteen extraction tests were carried out, feeding about 120 g of product into the extractor for each test.

Extraction was effected at 45°C, 150 bar, with a CO2 throughput of 1.72 kg/h and an extraction time of 2 hours. After each test the refined product and the extracted paraffins are discharged, and the extractor was fed with a new charge of material to be extracted.

The refined products and extracts of all the 15 tests were pooled and analysed.

Analysis of the refined product gave the following values:

______________________________________
paraffinsulfonic acids
69.73% by weight
C12 -C18 n-paraffins
0.55% by weight
H2 O 19.58% by weight
H2 SO4 10.14% by weight
______________________________________

200.2 g of a crude mixture (as heretofore defined) of paraffinsulfonic acids having the composition indicated in Example 1 were treated at ambient temperature with 32.2 g of 96 wt % H2 SO4.

After separating the lower phase (88.8 g), a fraction of the upper phase (102.5 g) was extracted with supercritical CO2 under the conditions described in Example 2.

Analysis of the refined product gave the following values:

______________________________________
paraffinsulfonic acids
60.55% by weight
C12 -C18 paraffins
0.09% by weight
H2 O 27.77% by weight
H2 SO4 11.59% by weight
______________________________________

199.9 g of a crude mixture (as heretofore defined) of paraffinsulfonic acids having the composition indicated in Example 1 were treated at ambient temperature with 16.75 g of 96 wt % H2 SO4.

A lower phase was separated (45.4 g) consisting of H2 O and H2 SO4, and the upper phase containing all the paraffinsulfonic acids and paraffins present in the initial crude mixture was extracted with supercritical CO2 under the conditions described in Example 2.

Analysis of the refined product gave the following values:

______________________________________
paraffinsulfonic acids
43.98% by weight
C12 -C18 paraffins
0.07% by weight
H2 O 39.89% by weight
H2 SO4 16.06% by weight
______________________________________

96 wt % H2 SO4 was added to 200.3 g of a crude mixture (as heretofore defined) of paraffinsulfonic acids having the composition indicated in Example 1 and kept under efficient agitation at 22° C., until persistent turbidity was obtained at 22°C

The quantity of H2 SO4 added was 9.65 g. 114.6 g of this mixture were extracted with supercritical CO2 under the conditions described in Example 2.

Analysis of the refined product gave the following values:

______________________________________
paraffinsulfonic acids
33.72% by weight
C12 -C18 n-paraffins
0.28% by weight
H2 O 50.12% by weight
H2 SO4 15.88% by weight
______________________________________

96 wt % H2 SO4 was added to 200.5 g of a crude mixture (as heretofore defined) of paraffinsulfonic acids having the composition indicated in Example 1 and kept under efficient agitation at 45° C., until persistent turbidity was obtained at 45°C

The quantity of H2 SO4 added was 6.10 g. 119.25 g of this mixture were extracted with supercritical CO2 under the conditions described in Example 2.

Analysis of the refined product gave the following values:

______________________________________
paraffinsulfonic acids
33.53% by weight
C12 -C18 n-paraffins
1.49% by weight
H2 O 49.38% by weight
H2 SO4 15.60% by weight
______________________________________

200.1 g of a crude mixture (as heretofore defined) of paraffinsulfonic acids having the composition indicated in Example 1 were treated at ambient temperature with 54.6 g of 70% H2 SO4 (aqueous solution). A lower phase was separated (107.5 g) consisting of H2 O and H2 SO4.

127.2 g of the upper phase were extracted with supercritical CO2 under the conditions described in Example 2.

Analysis of the refined product gave the following values:

______________________________________
paraffinsulfonic acids
58.185% by weight
C12 -C18 n-paraffins
0.025% by weight
H2 O 29.680% by weight
H2 SO4 12.110% by weight
______________________________________

76.1 g of a crude mixture (as heretofore defined) of paraffinsulfonic acids having the composition indicated in Example 1 were extracted with supercritical CO2 under the conditions described in Example 2.

Analysis of the refined product gave the following values:

______________________________________
paraffinsulfonic acids
33.33% by weight
C12 -C18 paraffins
8.99% by weight
H2 O 47.11% by weight
H2 SO4 10.60% by weight
______________________________________

In this case the paraffin extraction was found to be totally insufficient.

The crude mixture (as heretofore defined) of paraffinsulfonic acids having the composition indicated in Example 1 was extracted with supercritical CO2 under various operating conditions. The operating conditions used and the results of the analyses carried out on the refined products are given in Table 1.

TABLE 1
__________________________________________________________________________
ANALYSIS OF REFINED
MIX- PRODUCT % WT
EXAM-
TURE
EXTRACTION
EXTRACTION
EXTRACTION
CO2
PARAFFIN- SUL-
PLE FED TEMP. PRESSURE TIME RATE SULFONIC
PARAF- FURIC
No. g °C.
bar hours kg/h ACIDS FINS WATER
ACID
__________________________________________________________________________
9 124.1
33 300 1 1.07 28.74 18.56
43.79
8.91
10 125.2
35 150 1 1.80 27.80 14.84
46.84
10.52
11 125.9
40 150 1 1.80 28.65 11.55
49.70
10.10
12 124.2
40 150 3 1.80 31.99 11.37
45.94
10.70
13 124.3
40 300 2 1.40 29.50 11.22
48.67
10.61
14 123.9
45 200 1 1.46 31.40 11.95
46.78
9.87
15 124.3
50 350 1 1.11 32.82 8.20
48.50
10.48
16 124.2
86 300 2 1.07 43.80 2.21
45.18
8.81
__________________________________________________________________________

Faggian, Lucio, Platone, Edoardo, Franco, Cosimo, Castellano, Maurizio

Patent Priority Assignee Title
6007722, Oct 11 1995 Chematur Engineering AB Extraction method
Patent Priority Assignee Title
2875257,
3033898,
3861442,
4269789, Dec 31 1979 Phillips Petroleum Company Petroleum sulfonation
4361520, Jul 26 1979 MARATHON OIL COMPANY, AN OH CORP Refinement of sulfonated hydrocarbons
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